A copula-based multivariate drought indicator to design and monitor nature-based solutions
- 1University of Surrey , Faculty of Engineering and Physical Sciences, Global Centre for Clean Air Research, Civil and Environmental Engineering Department, United Kingdom of Great Britain and Northern Ireland (sd0059@surrey.ac.uk)
- 2Department of Physics and Astronomy (DIFA), Alma Mater Studiorum-University of Bologna, Bologna, Italy
- 3Innovative Technologies Center S.A., Alketou Str. 25, 11633 Athens, Greece
- 4Department of Geography, Harokopio University of Athens (HUA), El. Venizelou Str. 70, 17671, Athens, Greece
- 5Agricultural University of Athens, Laboratory of Mineralogy-Geology, Iera Odos 75, 118 55 Athens, Greece
- 6Region of Sterea Ellada, Kalivion 2, 351 32, Lamia, Greece
Abstract
Droughts are comprehensive and complex naturally occurring hazards in any climatic region around the world and often result in the loss of life and severe ecosystem damage. Drought monitoring is usually based on single-variables that may not represent the corresponding risk appropriately to its multiple causation and impact characteristics under current and future climate scenarios. In order to address this issue, the multidimensional copulas function, which is a flexible statistical tool, could be applied to develop multivariate drought indicators and solve the complicated and nonlinear associations. The aim of this paper is to develop reliable designing, monitoring and prediction indicators for the proper assessment and intervention of drought risk by nature-based solutions (NBS). Using a copula-based multivariate drought indicator (CMDI) that considers all possible variables related to meteorological, agricultural and hydrological droughts is essential for better drought risk assessment and intervention. The CMDI was developed by integrating univariate marginal cumulative distribution functions of meteorological (precipitation), agricultural (soil moisture) and hydrological (streamflow) variables into their joint cumulative distribution function. CMDI was then applied to the selected study catchment (Po Valley, Italy and Spercheios River, Greece) using hydro-meteorological data from gauging stations and ERA5 gridded data for the period 1979-2017. The result of CMDI showed moderate, severe and extreme drought frequencies in the two selected catchments. The constructed CMDI captured more severe to extreme drought occurrence than the considered single drought indicators. This proved that the CMDI could appropriately represent the complex and interrelated natural variables. The uncertainty analysis based on Monte Carlo experiments confirmed that CMDI is a more robust and reliable approach for assessing, planning and designing a nature-based intervention for drought risk. The findings of this research can provide a reliable way to develop approaches that can be used for assessing and predicting non-linearly related variables or any risk that may occur simultaneously or cumulatively over time.
Keywords: Drought risk; multidimensional copulas; multivariate indicators, uncertainty analysis; frequency
Acknowledgements: This work is carried out under the framework of OPERANDUM (OPEn-air laboRAtories for Nature baseD solUtions to Manage hydro-meteo risks) project, which is funded by the Horizon 2020 under the Grant Agreement No: 776848.
How to cite: Debele, S., Sahani, J., Porcù, F., Aragão, L., Spyrou, C., Loupis, M., Charizopoulos, N., Di Sabatino, S., and Kumar, P.: A copula-based multivariate drought indicator to design and monitor nature-based solutions, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-13912, https://doi.org/10.5194/egusphere-egu2020-13912, 2020
